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Narrow or Monodisperse, Physically Cross-Linked, and “Living” Spherical Polymer Particles by One-Stage RAFT Precipitation Polymerization
writer:Congguang Zheng, Yan Zhou, Yanpeng Jiao, Huiqi Zhang*
keywords:"Living" polymer microspheres, physically cross-linked, monodisperse, one-stage RAFT precipitation polymerization
source:期刊
specific source:Macromolecules 2019, 52, 143-156.
Issue time:2019年

Controlled preparation of narrow or monodisperse, physically cross-linked, and “living” spherical polymer particles by one-stage reversible addition?fragmentation chain transfer (RAFT) precipitation polymerization (RAFTPP) is described for the first time. The introduction of RAFT polymerization mechanism into precipitation polymerization system, together with the use of methacrylic acid (MAA) (capable of forming hydrogen bonding) as the monomer, allows ready generation of uniform spherical poly(MAA) (PMAA) particles with surface-bound “living” dithioester groups, easily tunable sizes, and low molecular weights in the absence of any cross- linking monomer. The polymerization parameters (i.e., monomer loading, molar ratio of the RAFT agent to free radical initiator, and polymerization temperature) showed much influence on the morphologies and yields of PMAA particles, and their simple adjustment allows fine-tuning of “living” PMAA particle sizes. The presence of dithioester groups on such PMAA particles was confirmed not only by their light pink color and characteristic UV?vis absorbance peak of dithioester units but also by their capability of directly grafting cross-linked apolar polymer shells. Some uniform “living” PMAA-based functional copolymer microspheres were also prepared in a one-stage process by simply incorporating glycidyl methacrylate, 2-hydroxyethyl methacrylate, or a fluorescent monomer into the RAFTPP of MAA, demonstrating the high versatility and general applicability of the RAFTPP system. The polymerization of MAA in RAFTPP proved to occur both in the continuous phase and on PMAA particle surfaces instead of inside particles, and a combined “grafting from” and “grafting to” particle growth mechanism is proposed for RAFTPP.